Antisense oligonucleotide as a new technology application for CsLOB1 gene silencing aiming citrus canker resistance.

Citrus canker disease, caused by Xanthomonas citri subsp. citri, poses a significant threat to global citrus production. The control of the disease in the field relies mainly on the use of conventional tools such as copper compounds, which are harmful to the environment and could lead to bacterial resistance. This scenario stresses the need for new and sustainable technologies to control phytopathogens, representing a key challenge in developing studies that translate basic into applied knowledge. During infection, X. citri subsp. citri secretes a transcriptional activator-like effector that enters the nucleus of plant cells, activating the expression of the canker susceptibility gene LATERAL ORGAN BOUNDARIES 1 (LOB1). In this study, we explored the use of antisense oligonucleotides (ASOs) with phosphorothioate modifications to transiently inhibit the gene expression of CsLOB1 in Citrus sinensis. We designed and validated three potential ASO sequences, which led to a significant reduction in disease symptoms compared to the control. The selected ASO3-CsLOB1 significantly decreased the expression level of CsLOB1 when delivered through two distinct delivery methods and the reduction of the symptoms ranged from approximately 15% to 83%. Notably, plants treated with ASO3 did not exhibit an increase in symptoms development over the evaluation period. This study highlights the efficacy of ASO technology, based on short oligonucleotide chemically modified sequences, as a promising tool for controlling phytopathogens without the need for genetic transformation or plant regeneration. Our results demonstrate the potential of ASOs as a biotechnological tool for the management of citrus canker disease.

Differential expression of genes potentially related to the callogenesis and in situ hybridization of SERK gene in macaw palm (Acrocomia aculeata Jacq.) Lodd. ex Mart.

For the purpose of understanding the molecular processes triggered during callus formation in macaw palm, the expression of seven genes potentially involved in this process, identified in previous studies and from the literature, was investigated by RT-qPCR. In addition, in situ hybridization of the SERK gene was performed. Leaf tissues from adult plants from two macaw palm accession were inoculated in a medium combined with Picloram at a concentration of 450 µM to induce callus. The expression analysis was performed from leaf samples from two accessions of different origins (Municipalities of Tiros, MG, and Buriti Vermelho, DF, Brazil), which are characterized as non-responsive (NR) and responsive (R), respectively. The material was collected before callus induction (0 DAI, initial day) and 120 days after callus induction (120 DAI). Genes related to development (SERK, OASA, EF1, ANN1) and stress (LEA, CAT2, and MDAR5) were evaluated. The results obtained showed that all the genes involved with the development had their expressions downregulated at 0 DAI when the accession R was compared with the accession NR. On the other hand, it was possible to observe that these genes were upregulated at 120 DAI. The LEA stress gene showed a tendency to increase expression in the NR accession, while the R accession showed decreased expression and the CAT2 and MDAR5 genes showed upregulation in both accessions. In situ hybridization showed SERK transcripts in the vascular bundles, indicating the expression of SERK in this region, in addition to its expression in calluses. The results obtained in this study support our hypothesis that the regulation of genes involved in the control of oxidative stress and development is crucial for the formation of calluses in macaw palm.

Proteomic Insights of Cowpea Response to Combined Biotic and Abiotic Stresses.

The co-occurrence of biotic and abiotic stresses in agricultural areas severely affects crop performance and productivity. Drought is one of the most adverse environmental stresses, and its association with root-knot nematodes further limits the development of several economically important crops, such as cowpea. Plant responses to combined stresses are complex and require novel adaptive mechanisms through the induction of specific biotic and abiotic signaling pathways. Therefore, the present work aimed to identify proteins involved in the resistance of cowpea to nematode and drought stresses individually and combined. We used the genotype CE 31, which is resistant to the root-knot nematode Meloidogyne spp. And tolerant to drought. Three biological replicates of roots and shoots were submitted to protein extraction, and the peptides were evaluated by LC-MS/MS. Shotgun proteomics revealed 2345 proteins, of which 1040 were differentially abundant. Proteins involved in essential biological processes, such as transcriptional regulation, cell signaling, oxidative processes, and photosynthesis, were identified. However, the main defense strategies in cowpea against cross-stress are focused on the regulation of hormonal signaling, the intense production of pathogenesis-related proteins, and the downregulation of photosynthetic activity. These are key processes that can culminate in the adaptation of cowpea challenged by multiple stresses. Furthermore, the candidate proteins identified in this study will strongly contribute to cowpea genetic improvement programs.

A Capsid Protein Fragment of a Fusagra-like Virus Found in Carica papaya Latex Interacts with the 50S Ribosomal Protein L17.

Papaya sticky disease is caused by the association of a fusagra-like and an umbra-like virus, named papaya meleira virus (PMeV) and papaya meleira virus 2 (PMeV2), respectively. Both viral genomes are encapsidated in particles formed by the PMeV ORF1 product, which has the potential to encode a protein with 1563 amino acids (aa). However, the structural components of the viral capsid are unknown. To characterize the structural proteins of PMeV and PMeV2, virions were purified from Carica papaya latex. SDS-PAGE analysis of purified virus revealed two major proteins of ~40 kDa and ~55 kDa. Amino-terminal sequencing of the ~55 kDa protein and LC-MS/MS of purified virions indicated that this protein starts at aa 263 of the deduced ORF1 product as a result of either degradation or proteolytic processing. A yeast two-hybrid assay was used to identify Arabidopsis proteins interacting with two PMeV ORF1 product fragments (aa 321-670 and 961-1200). The 50S ribosomal protein L17 (AtRPL17) was identified as potentially associated with modulated translation-related proteins. In plant cells, AtRPL17 co-localized and interacted with the PMeV ORF1 fragments. These findings support the hypothesis that the interaction between PMeV/PMeV2 structural proteins and RPL17 is important for virus-host interactions.

Repurposing streptomycin and chloramphenicol against bacterial pathogens by combination with diminazene aceturate.

Bacterial resistance is a threat to health worldwide, mainly due to reduced effective treatment. In this context, the search for strategies to control such infections and suppress antimicrobial resistance is necessary. One of the strategies that has been used is combination therapy. In the present work, we investigated the in vitro efficacy of the antimicrobials diminazene aceturate (DA), chloramphenicol (CHL), and streptomycin (STP) alone and in combination against Escherichia coli, Klebsiella pneumoniae, and Staphylococcus aureus clinical isolates. DA was capable of inhibiting all strains with MIC of 25-400 µg mL-1, while STP and CHL showed antibacterial activity with minimum inhibitory concentration (MICs) of ≤3.12-400 µg mL-1. The combination of aceturate with STP showed synergism toward almost all Gram-negative bacteria, with fractional inhibitory concentration index (FICIs) of 0.09-0.37. In addition, for CHL and aceturate, synergisms for Gram-negative and -positive strains were observed. A time-kill assay against E. coli revealed that the aceturate and STP combination can inhibit bacterial growth in a shorter time when compared with single antibiotics. In addition, antimicrobials did not show hemolytic activity even at the highest concentrations used. Therefore, the antimicrobial combinations presented in this work showed important results, demonstrating that combined therapy can be used as an alternative strategy for pathogen control.

Overexpression of cotton genes GhDIR4 and GhPRXIIB in Arabidopsis thaliana improves plant resistance to root-knot nematode (Meloidogyne incognita) infection.

Gossypium hirsutum L. represents the best cotton species for fiber production, thus computing the largest cultivated area worldwide. Meloidogyne incognita is a root-knot nematode (RKN) and one of the most important species of Meloidogyne genus, which has a wide host range, including cotton plants. Phytonematode infestations can only be partially controlled by conventional agricultural methods, therefore, more effective strategies to improve cotton resistance to M. incognita disease are highly desirable. The present study employed functional genomics to validate the involvement of two previously identified candidate genes, encoding dirigent protein 4-GhDIR4 and peroxiredoxin-2-GhPRXIIB, in cotton defense against M. incognita. Transgenic A. thaliana plant lines overexpressing GhDIR4 and GhPRXIIB genes were generated and displayed significantly improved resistance against M. incognita infection in terms of female nematode abundance in the roots when compared to wild-type control plants. For our best target-gene GhDIR4, an in-silico functional analysis, including multiple sequence alignment, phylogenetic relationship, and search for specific protein motifs unveiled potential orthologs in other relevant crop plants, including monocots and dicots. Our findings provide valuable information for further understanding the roles of GhDIR and GhPRXIIB genes in cotton defense response against RKN nematode. Supplementary Information: The online version contains supplementary material available at 10.1007/s13205-022-03282-4.

Proteome dataset of Hemileia vastatrix by LC-MS/MS label-free identification.

Here we describe the proteome of the fungus Hemileia vastatrix by label free mass spectrometry (LC-MS/MS). H. vastatrix is the causal agent of coffee rust disease, causing great economic losses in this crop. The objective of our work was to identify H. vastatrix proteins potentially involved in host colonization and infection, by exploring the shotgun proteomics approach. A total of 742 proteins were identified and are associated with several crucial molecular functions, biological processes, and cellular components. The proteins identified contribute to a better understanding of the metabolism of the fungus and may help identify target proteins for the development of specific drugs in order to control coffee rust disease. All data can be accessed at the Centre for Computational Mass Spectrometry - MassIVE MSV000087665 -https://massive.ucsd.edu/ProteoSAFe/dataset.jsp?task=cc71ad75f767451abe72dd1ce0019387.

NBS-LRR-WRKY genes and protease inhibitors (PIs) seem essential for cowpea resistance to root-knot nematode.

Cowpea (Vigna unguiculata L. Walp) is a legume of great economic importance, however it is highly affected by nematodes. The present work aimed to identify proteins and genes involved in nematode resistance by proteomic and transcriptomic analysis. Plants of a genotype resistant (CE31) to root-knot nematode (Meloidogyne spp.) were collected 12 days after inoculation with Meloidogyne incognita and the total proteins and RNA were extracted from the root samples. Shotgun proteomic analysis was performed using an Orbitrap Elite mass spectrometer and the construction and sequencing of cDNA libraries were carried out in a Hi-Seq 2000 sequencing system. The proteomic and transcriptomic analyses revealed key processes involved in cowpea defense and some interesting candidates were further analyzed by RT-qPCR. Proteins and genes involved in essential biological processes were differentially accumulated such as, regulation of transcription, cell wall stiffening and microtubule-based process. However, the main defense strategies of Vigna unguiculata seem to be focused on the interaction of NBS-LRR and WRKY genes for the activation of R genes, production of protease inhibitors and maintenance of actin cytoskeleton. These are key processes that can culminate in the suppression of giant cell formation and consequently in the development of Meloidogyne incognita. SIGNIFICANCE: In this study, we identified proteins and transcripts regulated in cowpea resistant to the nematode Meloidogyne spp. upon inoculation. The results revealed key candidate genes involved in the activation of R genes, the production of protease inhibitors and maintenance of the actin cytoskeleton. These processes might be essential for cowpea resistance, as they can impede nematode nutrition, giant cell formation and consequently the development of Meloidogyne incognita.

Priming of defense-related genes in Brassica oleracea var. capitata using concentrated metabolites produced by Rhizobium tropici CIAT 899.

To verify the potential of metabolites extracted from Rhizobium tropici to trigger the priming of defense responses in cruciferous plants, we analyzed the expression of defense-related genes by qRT-PCR. Brassica oleracea var. capitata, susceptible to Xanthomonas campestris pv. campestris, were grown in greenhouse conditions. At 18 days after sowing, plants were inoculated with 1 mL of 1% concentrated metabolites produced by R. tropici (CM-RT) in the root. In a second experiment, leaves were sprayed with 1 mL of a solution containing 1% CM-RT. Aerial and root tissue were collected separately at 0 (non-treated control condition), 24, and 48 h after application, submitted to RNA extraction and gene expression analysis by qRT-PCR. The results showed that, after root treatment with CM-RT, most evaluated genes were upregulated at 24 h after application and downregulated at 48 h after application in roots, while in leaves, genes were downregulated both at 24 and 48 h after application. On the other hand, leaf treatment with CM-RT showed that most evaluated genes in leaves and roots were upregulated at 24 and 48 h after application. These results indicate that the effect of CM-RT applied in roots seems restricted to the applied region and is not sustained, while the application in leaves results in a more systemic response and maintenance of the effect of CM-RT for a longer period. The results obtained in this study emphasize the biotechnological potential of using metabolites of R. tropici as an elicitor of active defense responses in plants.

CRISPR Genome Editing Technology: A Powerful Tool Applied to Developing Agribusiness.

The natural increase of the world's population implies boosting agricultural demand. In the current non-optimistic global scenario, where adverse climate changes come associated with substantial population growth, the main challenge in agribusiness is food security. Recently, the CRISPR/Cas system has emerged as a friendly gene editing biotechnological tool, enabling a precise manipulation of genomes and enhancement of desirable traits in several organisms. This review highlights the CRISPR/Cas system as a paramount tool for the improvement of agribusiness products and brings up-to-date findings showing its potential applications in improving agricultural-related traits in major plant crops and farm animals, all representing economic-relevant commodities responsible for feeding the world. Several applied pieces of research have successfully demonstrated the CRISPR/Cas ability in boosting interesting traits in agribusiness products, including animal productivity and welfare, crop yield growth, and seed quality, reflecting positive impacts in both socioeconomics and human health aspects. Hence, the CRISPR/Cas system has revolutionized bioscience and biotechnology, and its concrete application in agribusiness goods is on the horizon.

Shotgun proteomics coupled to transient-inducible gene silencing reveal rice susceptibility genes as new sources for blast disease resistance.

A comparative proteomic analysis between two near-isogenic rice lines, displaying a resistant and susceptible phenotype upon infection with Magnaporthe oryzae was performed. We identified and validated factors associated with rice disease susceptibility, representing a flourishing source toward a more resolute rice-blast resistance. Proteome profiles were remarkably different during early infection (12 h post-inoculation), revealing several proteins with increased abundance in the compatible interaction. Potential players of rice susceptibility were selected and gene expression was evaluated by RT-qPCR. Gene Ontology analysis disclosed susceptibility gene-encoded proteins claimed to be involved in fungus sustenance and suppression of plant immunity, such as sucrose synthase 4-like, serpin-ZXA-like, nudix hydrolase15, and DjA2 chaperone protein. Two other candidate genes, picked from a previous transcriptome study, were added into our downstream analysis including pyrabactin resistant-like 5 (OsPYL5), and rice ethylene-responsive factor 104 (OsERF104). Further, we validated their role in susceptibility by Transient-Induced Gene Silencing (TIGS) using short antisense oligodeoxyribonucleotides that resulted in a remarkable reduction of foliar disease symptoms in the compatible interaction. Therefore, we successfully employed shotgun proteomics and antisense-based gene silencing to prospect and functionally validate rice potential susceptibility factors, which could be further explored to build rice-blast resistance. SIGNIFICANCE: R gene-mediated disease resistance is race-specific and often not durable in the field. More recently, advancements in new breeding techniques (NBTs) have made plant disease susceptibility genes (S-genes) a new target to build a broad spectrum and more durable resistance, hence an alternative source to R-genes in breeding programs. We successfully coupled shotgun proteomics and gene silencing tools to prospect and validate new rice-bast susceptibility genes that can be further exploited toward a more resolute blast disease resistance.

BiP-overexpressing soybean plants display accelerated hypersensitivity response (HR) affecting the SA-dependent sphingolipid and flavonoid pathways.

Biotic and abiotic environmental stresses have limited the increase in soybean productivity. Overexpression of the molecular chaperone BiP in transgenic plants has been associated with the response to osmotic stress and drought tolerance by maintaining cellular homeostasis and delaying hypersensitive cell death. Here, we evaluated the metabolic changes in response to the hypersensitivity response (HR) caused by the non-compatible bacteria Pseudomonas syringae pv. tomato in BiP-overexpressing plants. The HR-modified metabolic profiles in BiP-overexpressing plants were significantly distinct from the wild-type untransformed. The transgenic plants displayed a lower abundance of HR-responsive metabolites as amino acids, sugars, carboxylic acids and signal molecules, including p-aminobenzoic acid (PABA) and dihydrosphingosine (DHS), when compared to infected wild-type plants. In contrast, salicylic acid (SA) biosynthetic and signaling pathways were more stimulated in transgenic plants, and both pathogenesis-related genes (PRs) and transcriptional factors controlling the SA pathway were more induced in the BiP-overexpressing lines. Furthermore, the long-chain bases (LCBs) and ceramide biosynthetic pathways showed alterations in gene expression and metabolite abundance. Thus, as a protective pathway against pathogens, HR regulation by sphingolipids and SA may account at least in part by the enhanced resistance of transgenic plants. GmNAC32 transcriptional factor was more induced in the transgenic plants and it has also been reported to regulate flavonoid synthesis in response to SA. In fact, the BiP-overexpressing plants showed an increase in flavonoids, mainly prenylated isoflavones, as precursors for phytoalexins. Our results indicate that the BiP-mediated acceleration in the hypersensitive response may be a target for metabolic engineering of plant resistance against pathogens.

Seasonal differences in seminal plasma proteins from two bovine breeds adapted to a subtropical climate.

This study was designed to evaluate the seasonal expression of seminal plasma proteins from two bovine breeds adapted to a subtropical climate and their associations with post-thawing sperm and environmental characteristics. Semen samples were obtained three times in summer and three times in winter from four Crioulo Lageano and four Angus bulls. Seminal plasma was obtained by centrifugation, and the other portion of the semen was cryopreserved. Seminal plasma proteins were identified by 2D-nanoUPLC-MSE. Post-thawing assessments of sperm kinetics, morphology and membrane integrity were performed. Environmental data such as air temperature, air humidity and black globe temperature (BGT) were recorded, and the temperature-humidity index (THI) was calculated in summer and winter. Results showed that the climate varied significantly between seasons. Although no statistical differences were observed in semen quality between breeds, the protein profiles varied within and between seasons. We suggest that the most critical proteins in summer affecting sperm characteristics were TIMP-2, DNase, Clusterin, CFAH and GPx6. TIMP-2 and DNase showed a higher abundance in Crioulo Lageano in comparison with Angus, while Clusterin, CFAH and GPx6 presented a lower abundance. To the best of our knowledge, this is the first report of a recently evolved type of glutathione peroxidase, GPx6, in seminal plasma of bovines. In winter, five proteins were considered to be more critical: BSP1, BSP3, CCL2, Sulfhydryl oxidase and TIMP-2. BSP1 and TIMP-2 showed a lower abundance while BSP3, CCL2 and Sulfhydryl oxidase presented a higher abundance in this season in Crioulo Lageano in comparison with Angus.

RESUMO: Este estudo foi desenvolvido para avaliar a expressão sazonal de proteínas plasmáticas seminais de duas raças bovinas adaptadas ao clima subtropical e suas associações com espermatozóides pós-descongelamento e características ambientais. Amostras de sêmen foram obtidas três vezes no verão e três no inverno de quatro touros Crioulo Lageano e quatro Angus. O plasma seminal foi obtido por centrifugação e outra porção do sêmen foi criopreservada. As proteínas plasmáticas seminais foram identificadas por 2D-nanoUPLC-MSE. Foram realizadas avaliações pós-descongelamento da cinética espermática, morfologia e integridade da membrana. Dados ambientais como temperatura do ar, umidade do ar e temperatura do globo negro (BGT) foram registrados, e o índice temperatura-umidade (THI) foi calculado no verão e no inverno. Os resultados mostraram que o clima variou significativamente entre as estações. Embora não tenham sido observadas diferenças estatísticas na qualidade do sêmen entre as raças, os perfis proteicos variaram dentro e entre as estações. Sugerimos que as proteínas mais críticas no verão que afetam as características espermáticas foram TIMP-2, DNase, Clusterin, CFAH e GPx6. TIMP-2 e DNase apresentaram maior abundância em Crioulo Lageano em comparação com Angus, enquanto Clusterin, CFAH e GPx6 apresentaram menor abundância. Até onde sabemos, este é o primeiro relato de um tipo recentemente desenvolvido de glutationa peroxidase, GPx6, no plasma seminal de bovinos. No inverno, cinco proteínas foram consideradas mais críticas: BSP1, BSP3, CCL2, sulfidril oxidase e TIMP-2. BSP1 e TIMP-2 apresentaram menor abundância, enquanto BSP3, CCL2 e Sulfidril oxidase apresentaram maior abundância nesta temporada em Crioulo Lageano em comparação com Angus.

Remodeling of the cell wall as a drought-tolerance mechanism of a soybean genotype revealed by global gene expression analysis.

Drought stress is major abiotic stress that affects soybean production. Therefore, it is widely desirable that soybean becomes more tolerant to stress. To provide insights into regulatory mechanisms of the stress response, we compared the global gene expression profiles from leaves of two soybean genotypes that display different responses to water-deficit (BR 16 and Embrapa 48, drought-sensitive and drought-tolerant, respectively). After the RNA-seq analysis, a total of 5335 down-regulated and 3170 up-regulated genes were identified in the BR16. On the other hand, the number of genes differentially expressed was markedly lower in the Embrapa 48, 355 up-regulated and 471 down-regulated genes. However, induction and expression of protein kinases and transcription factors indicated signaling cascades involved in the drought tolerance. Overall, the results suggest that the metabolism of pectin is differently modulated in response to drought stress and may play a role in the soybean defense mechanism against drought. This occurs via an increase of the cell wall plasticity and crosslink, which contributed to a higher hydraulic conductance (K f) and relative water content (RWC%). The drought-tolerance mechanism of the Embrapa 48 genotype involves remodeling of the cell wall and increase of the hydraulic conductance to the maintenance of cell turgor and metabolic processes, resulting in the highest leaf RWC, photosynthetic rate (A), transpiration (E) and carboxylation (A/C i). Thus, we concluded that the cell wall adjustment under drought is important for a more efficient water use which promoted a more active photosynthetic metabolism, maintaining higher plant growth under drought stress. Supplementary Information: The online version contains supplementary material available at 10.1007/s42994-021-00043-4.

Corrigendum: Proteomic Analysis and Functional Validation of a Brassica oleracea Endochitinase Involved in Resistance to Xanthomonas campestris.

[This corrects the article DOI: 10.3389/fpls.2019.00414.].

Proteomics unravels new candidate genes for Meloidogyne resistance in wild Arachis.

Arachis stenosperma is a wild peanut relative exclusive to South America that harbors high levels of resistance against several pathogens, including the peanut root-knot nematode (RKN) Meloidogyne arenaria. In this study, a proteomic survey of A. stenosperma-M. arenaria interaction using 2-DE and LC-MS/MS identified approximately 1400 proteins, out of which 222 were differentially abundant (DAPs) when RKN inoculated root samples were compared to the control. Most of these DAPs were assigned to functional categories related to plant responses to pathogens including stress, glycolysis, redox and tricarboxylic acid cycle. The comparison between the transcriptome (RNA-Seq) and proteome expression changes, showed that almost 55% of these DAPs encode genes with a similar expression trend to their protein counterparts. Most of these genes were induced during RKN infection and some were related to plant defense, such as MLP-like protein 34 (MLP34), cinnamoyl-CoA reductase 1 (CCR1), enolase (ENO), alcohol dehydrogenase (ADH) and eukaryotic translation initiation factor 5A (eIF5A). The overexpression of AsMLP34 in Agrobacterium rhizogenes transgenic roots in a susceptible peanut cultivar showed a reduction in the number of M. arenaria galls and egg masses, indicating that AsMLP34 is a promising candidate gene to be exploited in breeding programs for RKN control in peanut. SIGNIFICANCE: The use of an integrated approach to compare plant-nematode transcriptional and translational data enabled the identification of a new gene, AsMLP34, for Meloidogyne resistance.

MALDI TOF MS-profiling: Applications for bacterial and plant sample differentiation and biological variability assessment.

In this study, we evaluated the potential use of MALDI-TOF MS Profiling for the differentiation of biological samples submitted to different treatments. We compared the bacterium Xanthomonas campestris pv. campestris (Xcc), grown in culture medium and in vivo (recovered from the plant). Plant samples were also analyzed and included explants at different somatic embryogenesis (SE) stages, as well as leaves from Brassica oleracea and Arabidopsis thaliana inoculated with Xcc, at different time points. The results showed that bacteria and highly divergent plant samples, such as those from embryogenic stages, can be unequivocally differentiated and the clustering was in accordance with proteomic analysis performed by 2-DE. These results show an important application of MALDI-TOF MS Profiling to select and prioritize samples to be analyzed prior to more complex approaches including transcriptomics and proteomics. We also show that in plant-pathogen interactions, when more subtle differences are obtained, the main contribution of MALDI-TOF MS Profiling is in the assessment of experimental variability. This is relevant since reproducibility is a challenging issue when dealing with complex experimental conditions such as plant-pathogen interactions. We propose the use of MALDI-TOF MS Profiling to aid researchers in minimizing experimental variability unrelated to the condition being analyzed. SIGNIFICANCE: MALDI-Profiling offers an inexpensive, rapid and reliable approach for investigating the protein profile to assess sample differentiation and experimental variability in microorganisms and plants and can be highly useful to analyze samples prior to more complex and expensive techniques such as proteomics and transcriptomics.

Pan Proteome of Xanthomonas campestris pv. campestris Isolates Contrasting in Virulence.

Fully sequenced genomes of Xanthomonas campestris pv. campestris (Xcc) strains are reported. However, intra-pathovar differences are still intriguing and far from clear. In this work, the contrasting virulence between two isolates of Xcc - Xcc51 (more virulent) and XccY21 (less virulent) is evaluated by determining their pan proteome profiles. The bacteria are grown in NYG and XVM1 (optimal for induction of hrp regulon) broths and collected at the max-exponential growth phase. Shotgun proteomics reveals a total of 329 proteins when Xcc isolates are grown in XVM1. A comparison of both profiles reveals 47 proteins with significant abundance fluctuations, out of which, 39 show an increased abundance in Xcc51 and are mainly involved in virulence/adaptation mechanisms, genetic information processing, and membrane receptor/iron transport systems, such as BfeA, BtuB, Cap, Clp, Dcp, FyuA, GroEs, HpaG, Tig, and OmpP6. Several differential proteins are further analyzed by qRT-PCR, which reveals a similar expression pattern to the protein abundance. The data shed light on the complex Xcc pathogenicity mechanisms and point out a set of proteins related to the higher virulence of Xcc51. This information is essential for the development of more efficient strategies aiming at the control of black rot disease.

Mechanism of the drought tolerance of a transgenic soybean overexpressing the molecular chaperone BiP.

Drought is one of major constraints that limits agricultural productivity. Some factors, including climate changes and acreage expansion, indicates towards the need for developing drought tolerant genotypes. In addition to its protective role against endoplasmic reticulum (ER) stress, we have previously shown that the molecular chaperone binding protein (BiP) is involved in the response to osmotic stress and promotes drought tolerance. Here, we analyzed the proteomic and metabolic profiles of BiP-overexpressing transgenic soybean plants and the corresponding untransformed line under drought conditions by 2DE-MS and GC/MS. The transgenic plant showed lower levels of the abscisic acid and jasmonic acid as compared to untransformed plants both in irrigated and non-irrigated conditions. In contrast, the level of salicylic acid was higher in transgenic lines than in untransformed line, which was consistent with the antagonistic responses mediated by these phytohormones. The transgenic plants displayed a higher abundance of photosynthesis-related proteins, which gave credence to the hypothesis that these transgenic plants could survive under drought conditions due to their genetic modification and altered physiology. The proteins involved in pathways related to respiration, glycolysis and oxidative stress were not signifcantly changed in transgenic plants as compared to untransformed genotype, which indicate a lower metabolic perturbation under drought of the engineered genotype. The transgenic plants may have adopted a mechanism of drought tolerance by accumulating osmotically active solutes in the cell. As evidenced by the metabolic profiles, the accumulation of nine primary amino acids by protein degradation maintained the cellular turgor in the transgenic genotype under drought conditions. Thus, this mechanism of protection may cause the physiological activities including photosynthesis to be active under drought conditions.

Quantitative expression of microRNAs in Brassica oleracea infected with Xanthomonas campestris pv. campestris.

Brassica oleracea var. capitata (cabbage) is an economically important crop affected by black rot disease caused by Xanthomonas campestris pv. campestris (Xcc). MicroRNAs (miRNAs) play an important role in plant defense modulation and therefore the analysis of these molecules can help better understand plant-pathogen interactions. In this study, we report the differential expression of four miRNAs that seem to participate in the plant response to Xcc infection. Northern Blot and RT-qPCR techniques were used to measure miRNA expression in resistant (União) and susceptible (Kenzan) cultivars. From 6 miRNAs analyzed, 4 were detected and differentially expressed, showing a down- and upregulated expression profile in susceptible and resistant cultivars, respectively. These results suggest that miR156, miR167, miR169, and miR390 could play a role in B. oleracea resistance enhancement against Xcc and could be explored as potential resistance markers in B. oleracea-Xcc interaction.